CN214684538U - Sawing machine with positioning function for mold production - Google Patents

Abstract

The application relates to the technical field of sawing machines, and discloses a sawing machine is used in mould production with locate function, including lathe, frame, roof and cutting part, lathe and roof interval are installed in one side of frame, and cutting part sets up between lathe and roof, still includes clamping component, pushes down parts and locating part, clamping component and locating part interval are installed at the top of lathe, push down the top that parts installed at clamping component. The utility model has the advantages that: cooperate through clamping part and push down the part and will wait that the mould that cuts is fixed, prevent that the skew takes place for the mould position among the cutting process, and then make the cutting process in need not artifical manual pressing, improved the security of device, rethread locating part fixes a position the mould of waiting to cut, prevents that the length of mould cutting is inconsistent, has improved the cutting quality, makes moreover need not frequent measurement cutting length in follow-up cutting process, has improved work efficiency.

Description

Sawing machine with positioning function for mold production

Technical Field

The application relates to the technical field of sawing machines, in particular to a sawing machine with a positioning function for mold production.

Background

The sawing machine is a lift of accomplishing the saw roof beam under electrical control through hydraulic transmission system, the clamp of work piece is tight, can carry out the stepless speed regulation of feed speed through the governing valve, it needs the sawing machine among the prior art to carry out the fixed of position to saw cut to different material work pieces to reach, make the material need the manual work to press the stable cutting of assurance material in cutting process, easily take place the saw area and lead to the fact the condition of injury to the staff in the cutting process, and the sawing machine can't be treated the length of cutting the material and fix a position, make the cutting length of same batch cutting material inconsistent, lead to cutting quality to descend, need to design a mould production with locate function now and use the sawing machine to solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a sawing machine is used in mould production with locate function, including lathe, frame, roof and cutting part, one side in the frame is installed at lathe and roof interval, cutting part sets up between lathe and roof, still includes clamping part, pushes down parts and locating part, the top at the lathe is installed with the locating part interval to clamping part and locating part interval, push down the top at clamping part to push down parts and clamping part cooperate.

Further, the clamping component comprises a first fixed box, a first motor, a first rotating rod, a first bevel gear, two second bevel gears, two first screw rods, two first supporting plates and two clamping blocks, the first fixed box is arranged at the top of the machine tool, the first motor is arranged at one end of the first fixed box, the output end of the first motor penetrates through the side wall of the first fixed box and extends into the first fixed box, the two first supporting plates are vertically arranged in the first fixed box at intervals, two ends of the two first screw rods are respectively and rotatably connected with the corresponding first supporting plates and the first fixed box, the two second bevel gears are respectively arranged at one ends, opposite to the two first screw rods, of the other end of one first screw rod is fixedly connected with the output end of the first motor, the first rotating rod is rotatably arranged in the first fixed box, and first pivot pole is perpendicular setting with two first screw rods, first bevel gear cover is established on first pivot pole to first bevel gear meshes with two second bevel gears respectively mutually, two press from both sides tight piece and establish respectively on two first screw rods, and two press from both sides tight piece all with corresponding first screw rod threaded connection, the top of first fixed case is seted up respectively with two first sliding tray that press from both sides tight piece sliding fit, two the top of pressing from both sides tight piece passes two first sliding tray extension settings respectively.

Further, the lower pressing part comprises a second supporting plate, a second motor, a sliding block, a gear, a rack and a pressing plate, the second supporting plate is 20866;, the second supporting plate is arranged at the top of the first fixing box, the second motor is arranged at the top of the second supporting plate, the gear is arranged at the output end of the second motor, the bottom end of the sliding block penetrates through the top of the second supporting plate to be extended and arranged, the sliding block is in sliding connection with the second supporting plate, the rack is arranged on one side of the sliding block, the gear is meshed with the rack, the pressing plate is arranged at the bottom of the sliding block in a horizontal shape, the pressing plate is hinged to the sliding block, grooves matched with the two clamping blocks are formed in the pressing plate, and a stop block matched with the rack is arranged on one side of the top end of the sliding block.

Further, the positioning component comprises a second fixed box, a limiting component and an ash blocking component, the second fixed box is arranged at the top of the machine tool, a second sliding groove and two third sliding grooves which are respectively matched with the limiting component and the ash blocking component are formed in the second fixed box, the limiting component is arranged on one side of the second fixed box, the output end of the limiting component penetrates through the side wall of the second fixed box and extends into the second fixed box, the ash blocking component is arranged in the two third sliding grooves in a sliding mode, the limiting component comprises a knob, a second screw rod, a moving block, a positioning block, a fixing block, a clamping block, a telescopic rod and a first spring, the ash blocking component comprises a plurality of sliding teeth and a plurality of second springs, the plurality of sliding teeth are respectively arranged in the two third sliding grooves in a sliding mode, the sliding teeth are mutually meshed, one group of the plurality of second springs is respectively arranged at the rear ends of every two sliding teeth, one end of each second spring is fixedly connected with the corresponding sliding tooth, the other end of each second spring is fixedly connected with the corresponding third sliding groove, the second screw rod is rotatably arranged in the second fixed box, one end of the second screw rod penetrates through the second fixed box and is fixedly connected with the knob, the moving block is sleeved on the second screw rod and is in threaded connection with the second screw rod, the top end of the moving block penetrates through the second sliding groove and is fixedly connected with the bottom of the positioning block, the fixing block is arranged on one side of the second fixed box, one end of the telescopic rod penetrates through the fixing block and is fixedly connected with the clamping block, the clamping block is connected with the knob in a clamping mode, the second spring is sleeved on the telescopic rod, and the two ends of each second spring are fixedly connected with the fixing block and the telescopic rod respectively.

Furthermore, one side of the machine tool is provided with an ash storage box in a sliding mode, and a through hole communicated with the ash storage box is formed in the first fixing box.

The embodiment of the application adopts the following technical scheme:

when a die needs to be cut, firstly, the telescopic rod is pulled to drive the clamping block and the knob to be separated, then the knob is rotated according to the length to be cut, the positioning block is driven to slide in the second sliding groove to a set position, so that the cutting length does not need to be frequently measured in the subsequent cutting process, the working efficiency is improved, the positioning block sequentially pushes the sliding teeth on two sides into the two third sliding grooves in the sliding process, then the sliding teeth are driven to reset by the second spring, the chips generated by cutting are prevented from falling onto the second screw rod through the second sliding groove to cause the second screw rod to be clamped and incapable of rotating, then, the telescopic rod is loosened, the clamping block is driven by the first spring to be clamped with the knob again, the position of the positioning block is prevented from being deviated due to shaking of a machine tool in the cutting process, the cutting length of the die is prevented from being inconsistent, the cutting quality is improved, and then, one end of the die to be cut is abutted against the positioning block through the second supporting plate, the first motor and the second motor are driven to work synchronously again, the first motor works and a first screw fixedly connected with the output end of the first motor rotates, the first bevel gear is meshed with the two second bevel gears respectively to drive the other first screw to rotate synchronously, and then the two clamping blocks are driven to move relatively in the two first sliding grooves respectively to clamp the two sides of the die, the second motor works to drive the gear to rotate, the gear and the rack are meshed to drive the sliding blocks to move downwards, downward acting force is applied to the die to press the top of the die, so that the position of the die cannot deviate in the cutting process, manual pressing is not needed in the cutting process, and the safety of the device is improved.

The embodiment of the application adopts at least one technical scheme which can achieve the following beneficial effects:

the first motor and the second motor are driven to work to drive the two clamping blocks and the pressing plate respectively to fix the two sides and the top of the die to be cut, so that the die position is prevented from being deviated in the cutting process, manual pressing is not needed in the cutting process, and the safety of the device is improved.

And secondly, the positioning block is driven to slide in the second sliding groove by rotating the knob, and when the to-be-positioned block slides to a set position, the knob is clamped by the clamping block, so that the position of the positioning block is prevented from being deviated due to the shaking of a machine tool in the cutting process, the length of the die is prevented from being inconsistent, the cutting quality is improved, the cutting length is not required to be frequently measured in the subsequent cutting process, and the working efficiency is improved.

And thirdly, when the positioning block slides in the second sliding groove, the positioning block pushes the sliding teeth on two sides into two third sliding grooves in sequence, and the second spring drives the sliding teeth to reset, so that the chips generated by cutting are prevented from passing through the second sliding groove and falling into the second screw rod to cause the second screw rod to be clamped and cannot rotate.

Fourthly, one side through the lathe slides and is provided with the ash storage box, sets up the through-hole that is linked together with the ash storage box in the first fixed incasement for the piece that the cutting produced can not pile up and hinder the equipment operation in the first fixed incasement, has improved the practicality of device.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic cross-sectional view of a partial three-dimensional structure of the clamping member of the present invention;

fig. 3 is a schematic perspective view of the pressing member of the present invention;

fig. 4 is a schematic perspective view of the positioning member of the present invention at a first angle;

fig. 5 is a schematic sectional view of a second angle of the positioning member according to the present invention.

In the figure: the machine tool 1, the frame 2, the machine top 3, the cutting component 4, the clamping component 5, the first fixed box 51, the first motor 52, the first rotating rod 53, the first bevel gear 54, the second bevel gear 55, the first screw 56, the first supporting plate 57, the clamping block 58, the first sliding groove 59, the pressing component 6, the second supporting plate 61, the second motor 62, the sliding block 63, the gear 64, the rack 65, the pressing plate 66, the groove 67, the stop block 68, the positioning component 7, the second fixed box 71, the limiting component 72, the knob 721, the second screw 722, the moving block 723, the positioning block 724, the fixed block 725, the clamping block 726, the telescopic rod 727, the first spring 728, the ash blocking component 73, the sliding tooth 731, the second spring 732, the second sliding groove 74, the third sliding groove 75, the ash storage box 8 and the through hole 9.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The technical solutions provided by the embodiments of the present application are described in detail below with reference to the accompanying drawings.

In the present embodiment, as shown in fig. 1 to 5, a sawing machine with a positioning function for mold production comprises a machine tool 1, a frame 2, a machine top 3 and a cutting component 4, wherein the machine tool 1 and the machine top 3 are mounted on one side of the frame 2 at intervals, the cutting component 4 is arranged between the machine tool 1 and the machine top 3, the sawing machine further comprises a clamping component 5, a pressing component 6 and a positioning component 7, the clamping component 5 and the positioning component 7 are mounted on the top of the machine tool 1 at intervals, the pressing component 6 is mounted on the top of the clamping component 5, and the pressing component 6 is matched with the clamping component 5.

Specifically, the clamping member 5 includes a first fixed box 51, a first motor 52, a first rotating rod 53, a first bevel 54, two second bevel 55, two first screws 56, two first supporting plates 57 and two clamping blocks 58, the first fixed box 51 is installed at the top of the machine tool 1, the first motor 52 is installed at one end of the first fixed box 51, the output end of the first motor 52 penetrates through the side wall of the first fixed box 51 and extends into the first fixed box 51, the two first supporting plates 57 are installed in the first fixed box 51 at vertical intervals, the two ends of the two first screws 56 are respectively and rotatably connected with the corresponding first supporting plates 57 and the first fixed box 51, the two second bevel 55 are respectively installed at the opposite ends of the two first screws 56, one other end of the first screw 56 is fixedly connected with the output end of the first motor 52, the first rotating rod 53 is rotatably arranged in the first fixed box 51, the first rotating rod 53 is perpendicular to the two first screws 56, the first bevel gear 54 is sleeved on the first rotating rod 53, the first bevel gear 54 is respectively meshed with the two second bevel gears 55, the two clamping blocks 58 are respectively sleeved on the two first screws 56, the two clamping blocks 58 are both in threaded connection with the corresponding first screws 56, the top of the first fixed box 51 is provided with first sliding grooves 59 respectively in sliding fit with the two clamping blocks 58, the tops of the two clamping blocks 58 respectively penetrate through the two first sliding grooves 59 to extend, one first screw 56 fixedly connected with the output end of the first motor 52 is driven to rotate, the first bevel gear 54 is respectively meshed with the two second bevel gears 55 to drive the other first screw 56 to synchronously rotate, thereby driving the two clamping blocks 58 to move relatively in the two first sliding grooves 59 respectively to clamp the two sides of the mold.

Specifically, the lower pressing part 6 comprises a second supporting plate 61, a second motor 62, a sliding block 63, a gear 64, a rack 65 and a pressing plate 66, the second supporting plate 61 is in a shape of a v 20866, the second supporting plate 61 is mounted at the top of the first fixed box 51, the second motor 62 is mounted at the top of the second supporting plate 61, the gear 64 is mounted at the output end of the second motor 62, the bottom end of the sliding block 63 extends through the top of the second supporting plate 61, the sliding block 63 is slidably connected with the second supporting plate 61, the rack 65 is mounted at one side of the sliding block 63, the gear 64 is meshed with the rack 65, the pressing plate 66 is horizontally arranged at the bottom of the sliding block 63, the pressing plate 66 is hinged with the sliding block 63, a groove 67 matched with the two clamping blocks 58 is formed in the pressing plate 66, a stop 68 matched with the rack 65 is mounted at one side of the top end of the sliding block 63, the second motor 62 is driven to work to drive the gear 64 to rotate, the gear 64 is meshed with the rack 65 to drive the sliding block 63 to move downwards, downward acting force is given to the die, and the top of the die is pressed.

Specifically, the positioning component 7 includes a second fixed box 71, a limiting component 72 and an ash blocking component 73, the second fixed box 71 is installed at the top of the machine tool 1, the second fixed box 71 is provided with a second sliding groove 74 and two third sliding grooves 75 respectively matched with the limiting component 72 and the ash blocking component 73, the limiting component 72 is arranged at one side of the second fixed box 71, an output end of the limiting component 72 extends into the second fixed box 71 through a side wall of the second fixed box 71, the ash blocking component 73 is arranged in the two third sliding grooves 75 in a sliding manner, the limiting component 72 includes a knob 721, a second screw 722, a moving block 723, a positioning block 724, a fixed block 725, a clamping block 726, an expansion link 727 and a first spring 728, the second screw 722 is rotatably arranged in the second fixed box 71, one end of the second screw 722 passes through the second fixed box 71 and is fixedly connected with the knob 721, the moving block 723 is sleeved on the second screw 722, the moving block 723 is in threaded connection with the second screw 722, the top end of the moving block 723 passes through the second sliding groove 74 and is fixedly connected with the bottom of the positioning block 724, the fixing block 725 is installed on one side of the second fixing box 71, one end of the telescopic rod 727 passes through the fixing block 725 and is fixedly connected with the clamping block 726, the clamping block 726 is clamped and connected with the knob 721, the second spring 732 is sleeved on the telescopic rod 727, two ends of the second spring 732 are respectively fixedly connected with the fixing block 725 and the telescopic rod 727, the positioning block 724 is driven to slide in the second sliding groove 74 by rotating the knob 721, when the positioning block 724 slides to a given position, the knob 721 is clamped by the clamping block 726, so that the position of the positioning block 724 is prevented from shifting due to shaking of the machine tool 1 in the cutting process, and the length of the die is prevented from being inconsistent, the cutting quality is improved, the cutting length does not need to be frequently measured in the subsequent cutting process, and the working efficiency is improved.

Specifically, the dust blocking assembly 73 includes a plurality of sliding teeth 731 and a plurality of second springs 732, the plurality of sliding teeth 731 are respectively and relatively slidably disposed in two third sliding grooves 75, the opposing sliding teeth 731 are engaged with each other, two pairs of second springs 732 are respectively disposed at the rear ends of the plurality of sliding teeth 731, one end of each second spring 732 is fixedly connected to the corresponding sliding tooth 731, the other end of each second spring 732 is fixedly connected to the corresponding third sliding groove 75, when the positioning block 724 slides in the second sliding groove 74, the positioning block 724 sequentially pushes the sliding teeth 731 on both sides into the two third sliding grooves 75, and then the second springs 732 drive the sliding teeth 731 to reset, so as to prevent the cutting debris from falling onto the second screw 722 through the second sliding grooves 74 and causing the second screw 722 to be unable to rotate.

Specifically, one side of lathe 1 slides and is provided with ash storage box 8, set up the through-hole 9 that is linked together with ash storage box 8 in the first fixed box 51 for the piece that the cutting produced can not pile up and hinder the equipment operation in first fixed box 51, has improved the practicality of device.

The working principle of the embodiment of the application is as follows: when a die needs to be cut, firstly, the telescopic rod 727 is pulled to drive the clamping block 726 to be separated from the knob 721, then the knob 721 is rotated according to the length to be cut, the positioning block 724 is driven to slide in the second sliding groove 74 to a set position, so that the cutting length does not need to be frequently measured in the subsequent cutting process, the working efficiency is improved, the positioning block 724 sequentially pushes the sliding teeth 731 on the two sides into the two third sliding grooves 75 in the sliding process, then the second spring 732 drives the sliding teeth 731 to reset, the chips generated by cutting are prevented from falling onto the second screw 722 through the second sliding groove 74 to cause the second screw 722 to be clamped and incapable of rotating, then the telescopic rod 727 is loosened, the clamping block 726 is driven by the first spring 728 to be clamped with the knob 721 again, the position of the positioning block 724 is prevented from being deviated due to the shaking of the machine tool 1 in the cutting process, and the cutting length of the die is prevented from being inconsistent, the cutting quality is improved, then one end of the die to be cut passes through the second supporting plate 61 to be abutted against the positioning block 724, the first motor 52 and the second motor 62 are synchronously driven to work, the first motor 52 works, a first screw 56 fixedly connected with the output end of the first motor rotates, the first bevel gear 54 is respectively meshed with the two second bevel gears 55 to drive the other first screw 56 to synchronously rotate, thereby driving the two clamping blocks 58 to respectively and relatively move in the two first sliding grooves 59 to clamp the two sides of the mold, the second motor 62 works to drive the gear 64 to rotate, the gear 64 is meshed with the rack 65 to drive the sliding block 63 to move downwards, downward acting force is given to the mould to press the top of the mould, therefore, the position of the die cannot deviate in the cutting process, manual pressing is not needed in the cutting process, and the safety of the device is improved.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (5)

1. The utility model provides a sawing machine is used in mould production with locate function, includes lathe (1), frame (2), roof (3) and cutting part (4), lathe (1) and roof (3) interval are installed in one side of frame (2), cutting part (4) set up between lathe (1) and roof (3), its characterized in that: still include clamping component (5), push down parts (6) and locating component (7), clamping component (5) and locating component (7) interval are installed at the top of lathe (1), push down parts (6) and install the top at clamping component (5) to push down parts (6) and clamping component (5) cooperate.

2. The sawing machine with positioning function for mold production according to claim 1, wherein: the clamping component (5) comprises a first fixed box (51), a first motor (52), a first rotating rod (53), a first bevel gear (54), two second bevel gears (55), two first screw rods (56), two first supporting plates (57) and two clamping blocks (58), the first fixed box (51) is installed at the top of the machine tool (1), the first motor (52) is installed at one end of the first fixed box (51), the output end of the first motor (52) penetrates through the side wall of the first fixed box (51) and extends into the first fixed box (51), the two first supporting plates (57) are installed in the first fixed box (51) in a vertical interval mode, the two ends of the two first screw rods (56) are respectively and rotatably connected with the corresponding first supporting plates (57) and the first fixed box (51), the two second bevel gears (55) are respectively installed at one ends, opposite to the two first screw rods (56), the other end of the first screw rod (56) is fixedly connected with the output end of a first motor (52), the first rotating rod (53) is rotatably arranged in a first fixed box (51), the first rotating rod (53) is perpendicular to the two first screws (56), the first bevel gear (54) is sleeved on the first rotating rod (53), the first bevel gear (54) is respectively meshed with the two second bevel gears (55), the two clamping blocks (58) are respectively sleeved on the two first screw rods (56), and the two clamping blocks (58) are in threaded connection with the corresponding first screw rods (56), the top of the first fixed box (51) is provided with first sliding grooves (59) which are respectively in sliding fit with the two clamping blocks (58), and the tops of the two clamping blocks (58) respectively penetrate through the two first sliding grooves (59) to extend.

3. The sawing machine with positioning function for mold production according to claim 2, wherein: the pressing component (6) comprises a second supporting plate (61), a second motor (62), a sliding block (63), a gear (64), a rack (65) and a pressing plate (66), wherein the second supporting plate (61) is in a shape of 20866;, the second supporting plate (61) is installed at the top of the first fixing box (51), the second motor (62) is installed at the top of the second supporting plate (61), the gear (64) is installed at the output end of the second motor (62), the bottom end of the sliding block (63) passes through the top of the second supporting plate (61) to extend, the sliding block (63) is connected with the second supporting plate (61) in a sliding manner, the rack (65) is installed at one side of the sliding block (63), the gear (64) is meshed with the rack (65), the pressing plate (66) is horizontally arranged at the bottom of the sliding block (63), and the pressing plate (66) is hinged with the sliding block (63), set up on the pressfitting board (66) with two press from both sides tight piece (58) matched with recess (67), one side on sliding block (63) top is installed and is had dog (68) with rack (65) matched with.

4. The sawing machine with positioning function for mold production according to claim 1, wherein: the positioning component (7) comprises a second fixed box (71), a limiting component (72) and an ash blocking component (73), the second fixed box (71) is installed at the top of the machine tool (1), the second fixed box (71) is provided with a second sliding groove (74) and two third sliding grooves (75) which are respectively matched with the limiting component (72) and the ash blocking component (73), the limiting component (72) is arranged on one side of the second fixed box (71), the output end of the limiting component (72) penetrates through the side wall of the second fixed box (71) and extends into the second fixed box (71), the ash blocking component (73) is arranged in the two third sliding grooves (75) in a sliding manner, the limiting component (72) comprises a knob (721), a second screw rod (722), a moving block (723), a positioning block (724), a fixing block (725), a block (726), an expansion rod (727) and a first spring (728), the ash blocking component (73) comprises a plurality of sliding teeth (731) and a plurality of second springs (732), the sliding teeth (731) are arranged in the two third sliding grooves (75) in a sliding mode respectively, the sliding teeth (731) which are opposite to each other are meshed with each other, the second springs (732) are arranged at the rear ends of the sliding teeth (731) in a pairwise mode, one end of each second spring (732) is fixedly connected with the corresponding sliding tooth (731), the other end of each second spring (732) is fixedly connected with the corresponding third sliding groove (75), the second screw (722) is rotatably arranged in the second fixing box (71), one end of the second screw (722) penetrates through the second fixing box (71) and is fixedly connected with the knob (721), the moving block (723) is sleeved on the second screw (722), and the moving block (723) is in threaded connection with the second screw (722), the top end of the moving block (723) penetrates through the second sliding groove (74) and is fixedly connected with the bottom of the positioning block (724), the fixing block (725) is installed on one side of the second fixing box (71), one end of the telescopic rod (727) penetrates through the fixing block (725) and is fixedly connected with the clamping block (726), the clamping block (726) is connected with the knob (721) in a clamping mode, the second spring (732) is sleeved on the telescopic rod (727), and two ends of the second spring (732) are fixedly connected with the fixing block (725) and the telescopic rod (727) respectively.

5. The sawing machine with positioning function for mold production according to claim 2, wherein: one side of the machine tool (1) is provided with an ash storage box (8) in a sliding manner, and a through hole (9) communicated with the ash storage box (8) is formed in the first fixed box (51).

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